- Email: [email protected]
Development of a new serological assay for the diagnosis of Clostridium difficile infections with prognostic value
Journal Pre-proof Development of a new serological assay for the diagnosis of Clostridium difficile infections with prognostic value
Felix von Bechtolsheim, Adorjan Varga, Laszlo Szereday, Beata Polgar, Timea Balassa, Bela Kocsis, Zoltan Peterfi, Eva Miko PII:
S0167-7012(19)30680-3
DOI:
https://doi.org/10.1016/j.mimet.2019.105777
Reference:
MIMET 105777
To appear in:
Journal of Microbiological Methods
Received date:
11 August 2019
Revised date:
10 November 2019
Accepted date:
12 November 2019
Please cite this article as: F. von Bechtolsheim, A. Varga, L. Szereday, et al., Development of a new serological assay for the diagnosis of Clostridium difficile infections with prognostic value, Journal of Microbiological Methods (2018), https://doi.org/10.1016/ j.mimet.2019.105777
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© 2018 Published by Elsevier.
Journal Pre-proof Development of a new serological assay for the diagnosis of Clostridium difficile infections with prognostic value
Felix von Bechtolsheim5 , Adorjan Varga1,3 , Laszlo Szereday1, 2 , Beata Polgar1, 2 , Timea Balassa4 , Bela Kocsis1 , Zoltan Peterfi3 , Eva Miko1, 2
Department of Medical Microbiology and Immunology, Medical School, University of Pecs,
Pecs, Hungary
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3
Janos Szentagothai Research Centre, Pecs, Hungary
1st Department of Medicine, Division of infectious diseases, Medical School, University of
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2
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Pecs, Pecs, Hungary 4
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1
Department of Medical Biology and Central Electron Microscope Laboratory, Medical
Department of Visceral-, Thoracic- and Vascular Surgery, University Hospital, Technical
*
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University Dresden
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5
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School, University of Pecs, Pecs, Hungary
Correspondence:
Dr. Eva Miko M.D., Ph.D [email protected]
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Journal Pre-proof Abstract Purpose: The most common hospital-acquired enteral infection is caused by Clostridium difficile. Unfortunately, Clostridium difficile infections (CDI) are of high risk to recur and little is known about how to predict recurrences. Previous findings have shown that high risk for recurrence correlates with low levels of C. difficile toxin-A and -B specific antibodies suggesting the protective role of humoral immunity against bacterial virulence factors. Therefore, the aim of this study was to develop an immunoassay, which specifically measures
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C.difficile toxin-specific antibodies in the serum that might be correlated with the risk of recurrence.
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Methods: We developed a simple ELISA to measure the quantity of toxin-A and -B-specific
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antibodies in human serum. The assay was then used to test anti-toxin immune response in
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healthy controls, in patients with primary CDI and patients with CDI recurrence. Results: The developed assay is simple, reproducible and fast. When using this test in a small
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clinical trial our results showed a trend toward a higher antibody level in those patients with
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only one episode of CDI, whereas patients with recurrent CDI had less anti-toxin A or B-
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specific antibodies in their serum indicating inadequate C. difficile anti-toxin immunity may facilitate recurrent infections.
Conclusions: It has already been observed that low antibody levels are associated with recurrent CDI (Bauer et al. 2014). The findings of our clinical trial show a similar trend. Our developed ELISA test could help to conduct further research and it might be helpful in clinical use to detect patients of high risk for CDI recurrence.
Keywords: Clostridium difficile infection; ELISA assay; recurrence; antibodies; toxins
2
Journal Pre-proof Introduction Clostridium difficile is the most common cause of hospital acquired diarrhea, a major health concern and financial burden worldwide (Davies et al. 2014; Kwon, Olsen, and Dubberke 2015; Martin, Monaghan, and Wilcox 2016).
Even though it was discovered and
described already in 1935 for the first time, it took more than 40 years to link this pathogen to its various effects on human health. The hypervirulent strain B1/NAP1/027 of this Grampositive anaerobic spore-forming bacterium is primarily responsible for most of the recent
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outbreaks (Curry et al. 2007; Loo et al. 2005; McEllistrem et al. 2005). The highly transmissible and resistant spore enables the bacterial entry into the hospital environment and
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its continuous presence may lead to colonization of hospitalized patients. The clinical
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manifestation of the infection has a wide spectrum with high mortality rates. Particularly
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worrying is the fact, that in approximately 20-30% of patients with primary infection symptoms recur and recurrence rates are even higher after secondary and tertiary C. difficile
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infections (CDI) (Deshpande et al. 2015).
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Although the pathogenesis is multifactorial, the cytopathogenic effect of the two exotoxins, A
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and B is thought to be one of the major virulence factors of C.difficile along with being able to produce an endospore (Monaghan 2015). Considering that the risk of recurrence is up to 65% in certain patient populations it would be very useful to pre-estimate this risk and adapt the therapy to the given condition. Therefore, the study aimed to develop an immunoassay, which specifically measures C.difficile toxinspecific antibodies in the serum that might be correlated with the risk of recurrence. The protocol should be reliable in sensitivity and specificity, fast, uncomplicated and if possible, inexpensive. Furthermore, the developed ELISA-assay will be tested in a small clinical trial to assess the benefits and disadvantages of the test itself.
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Journal Pre-proof Materials and Methods Donors and Patients: Serum samples were collected by clinicians at the 1st Department of Medicine, Division of infectious diseases, Medical School, University of Pécs from December 2014 to May 2016. For measuring physiological C. difficile antibody levels, 15 serum samples were collected from anonymous blood donors without any history of C. difficile infection based on a detailed questionnaire. Additionally, 47 sera of patients with the diagnosis of CDI were analysed (age
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range 48-90; 29 women and 18 males). The diagnosis of CDI was based on the symptom diarrhoea and C. difficile toxin detection in the stool with an immune chromatography test.
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Blood samples were drawn on the 8th day of antibiotic therapy. After discharge, patients were
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followed up in order to notice recurrent CDI. According to a subsequent CDI recurrence
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(more than two weeks and less than eight weeks following the onset of the primary episode), patients were grouped in “primary CDI” and “recurrent CDI” groups. Serum samples were
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stored at -80 0 C until carrying out the experiments. Informed consent was taken from each
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donor and patient. The study was approved by the Local Ethical Committee of the Medical
Materials:
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School of the University of Pecs.
For the development of a C. difficile Toxin A and B antibody capture-ELISA test, the following reagents were used: for microplate: NUNC- MaxiSorp Immunoplate F96 (Thermo Scientific); for buffers: Trizma base (TRIS, Sigma Aldrich), Dulbecco’s PBS without Ca and Mg (PAA Laboratories GmbH); for coating: C. difficile Toxin A and Toxin B (Enzo Life Sciences), for blocking: bovine serum albumin (BSA, Sigma Aldrich), Superblock (PBS) Blocking Buffer (Thermo Scientific Inf.). Antibodies used in the ELISA test: primary antibody: rabbit polyclonal antibody to C. difficile Toxin A and Toxin B (Abcam), secondary antibody: polyclonal goat anti-rabbit immunoglobulin-HRP (DAKO), polyclonal goat anti4
Journal Pre-proof human immunoglobulin-HRP (DAKO). For detection: BD OptEIA TMB Substrate Reagent Set (Beckton Dickinson). ELISA development: Testing of different coating buffers for C. difficile anti-toxin capture ELISA For initial coating concentration 1g/ml protein was chosen for both C. difficile toxins. Three coating buffers with different pH were tested: TRIS buffer (pH 6,5), carbonate buffer (pH 9,6)
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and PBS buffer (pH 7,4). Immunoplates were coated with 100 l/well of Toxin A and Toxin B diluted in the different coating buffers and incubated overnight at 4 °C. After 3 x washing
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with PBS supplemented with 0,05% Tween washing buffer, wells were blocked with 200
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l/well of PBS supplemented with 0,5% gelatine and 0,1 % BSA for 1 hour at 37°C. Then
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plates were washed with 3 x 200 l of PBS-Tween washing buffer and rabbit polyclonal antibody to C. difficile Toxin A and Toxin B (at a dilution of 1: 100) and polyclonal goat anti-
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rabbit immunoglobulin (Ig)-HRP (at a dilution of 1: 2000) were applied as primary and
again
to
remove
the
unbound
antibody-enzyme
conjugates
and
TMB
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washed
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secondary antibodies. The plates were incubated for one hour at 37 °C. Next, the wells were
chromogen/substrate was added to develop the reaction. After 30 min (Toxin A) or 10 min (Toxin B) incubation at room temperature (RT) in the dark, the colour development was stopped by adding 100 l of 1M H2 SO 4 to the wells. The optical density (O.D.) of the coated positive (toxin coated wells + 1:100 rabbit polyclonal antibody to Toxin A/B + anti-rabbit IgHRP), coated negative (toxin coated wells + anti-rabbit Ig-HRP) and non-coated control wells (non-coated wells + 1:100 rabbit polyclonal antibody to Toxin A/B + anti-rabbit Ig-HRP) were determined at 450 nm with BMG Optima spectrophotometer. As shown in Table 1., TRIS-buffer provoked the lowest nonspecific reaction in the non-coated wells and gave the highest specific signal to noise value (O.D. of coated positive – 5
Journal Pre-proof
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O.D. of non-coated control wells) in both Toxin A and Toxin B ELISA.
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Journal Pre-proof TRIS buffer (pH 6,5)
Carbonate-buffer (pH 9,6) PBS buffer (pH 7,4)
coated positive: 2,694
coated positive: 2,524
coated positive: 2,908
coated negative: 0,053
coated negative: 0,001
coated negative: 0,005
non-coated control: 0,604
non-coated control: 0,826
non-coated control: 0,830
signal to noise: 2,090
signal to noise: 1,698
signal to noise: 2,078
coated positive: 3,942
coated positive: 3,562
coated positive: 3,810
coated negative: 0,000
coated negative: 0,005
coated negative: 0,006
non-coated control: 0,113
non-coated control: 0,164
non-coated control: 0,161
signal to noise: 3,829
signal to noise: 3,398
Toxin-A
signal to noise: 3,649
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Toxin-B
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Table 1.: Testing of different coating buffers. OD values of coated and non-coated control wells using different coating buffers and signal-to-noise values (O.D. of coated positive –
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Choosing the blocking buffer
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O.D. of non-coated control wells) are indicated.
In order to test the accuracy of the immunoassay, a collection of blood samples of
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definitely non-infected (negative) and definitely infected (positive) patients were gathered. The collected samples were pre-tested with C. difficile anti-toxin specific ELISA, then a negative and a positive serum pool were created by mixing the three most positive and three most negative samples, respectively. The obtained serum pools were used in further setup assays. For setup of blocking conditions three different blocking solutions were tested: skimmed milk solution (3%), BSA (5%) and Superblock buffer (Thermo Scientific). ELISAplates were coated with 1g/ml Toxin A and 0,5 g/ml Toxin B in TRIS-buffer (pH 6,5) overnight at 4 ºC. The next day the immunoplates were washed three times with PBS-Tween and 200l per well of skimmed milk and BSA solution were added to the wells for 1 hour at 7
Journal Pre-proof 37 °C. According to the manufacturer’s instruction, the Superblock buffer remained for 30 minutes on the ELISA-plates to block non-specific binding sites. After washing, 1:100 diluted positive and negative serum pools were applied to the toxin-coated and non-coated wells and incubated for 1 hour at 37°C. Then the plates were washed again and goat anti-human Ig-HRP (1:30000) was added to the wells. After one hour incubation at 37°C, the reaction was developed by TMB.
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As indicated in Table 2, the choice was made in favour of Superblock solution since
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this buffer resulted in the highest signal to noise value in the case of Toxin B (O.D. of toxin
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coated No1 wells – O.D. of non-coated No1 wells). Although 5% BSA solution was also
Toxin coated wells
Non-coated wells
1
2
3
2
3
Skimmed milk (3%)
0,555
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1
0,012
0,011
0,348
0,007
0,010
0,207
BSA (5%)
0,416
0,032
0,002
0,239
0,002
0,000
0,177
Superblock
0,573
0,021
0,002
0,376
0,004
0,000
0,197
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Toxin-B
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Toxin-A
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effective, skimmed milk solution (3%) showed less satisfying results in the experiments. Signal to noise
Toxin coated wells
Non-coated wells
Signal to noise
1
2
3
1
2
3
Skimmed milk (3%)
1,464
0,007
0,005
0,361
0,000
0,001
1,103
BSA (5%)
1,331
0,012
0,002
0,258
0,042
0,005
1,077
Superblock
1,933
0,075
0,070
0,522
0,066
0,069
1,411
Table 2.: Testing of different blocking conditions. OD values of coated and non-coated wells as well as the signal-to-noise values (O.D. of coated positive – O.D. of non-coated control wells) are indicated. Control wells: 8
Journal Pre-proof 1: + 1:100 positive serum pool + 1:30000 goat anti-human Ig-HRP 2: + 1:30000 goat anti-human Ig-HRP
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3: + 1:100 positive serum pool
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Journal Pre-proof Cross-titration The concentration of each component of the immunoassay was optimized by chessboard titration (CBT). During this process the amount of coating antigen and the dilution of primary antibody were tested against each other on a microtiter plate to examine the activities inherent at all the resulting combinations. In the case of this assay, three main test components - the antigen (C. difficile Toxin A/B), the primary antibody (positive and negative serum pool) and
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anti-species conjugate (goat anti-human Ig-HRP) - needed to be optimized. 1. Step: Titration of coating antigen to positive and negative test sera, using a goat anti-
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human Ig-HRP conjugate at a dilution recommended by the manufacturer.
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First Toxin A (titration range: 2-0,125g/ml) and Toxin B (titration range: 1-0,0625g/ml)
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were diluted in TRIS buffer (pH 6,5) and test plates were coated with 100 l/well of diluted antigens from column No1 to 5 for positive sera, and column No7 to 11 for negative sera.
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Column No6 and 12 received coating buffer only. After overnight incubation at 4 °C, plates
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were washed three times with 200 l PBS-Tween washing buffer (pH 7,4) and blocked with
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200 l/well of Superblock reagent for 30 minutes at room temperature to inhibit non-specific absorption of proteins. Then ELISA plates were washed again and two-fold serial dilutions of pooled positive and negative sera (titration range: from 1:100 to 1:3200 diluted in washing buffer) were added to the plate rows from B to G. Row A and H received sample diluent only. After incubation for 1 hour at 37 °C, plates were washed three times with washing buffer. Next 100l/well of goat anti-human Ig-HRP conjugate was added to the sample wells at a single dilution of 1:30000 in PBS-Tween supplemented with 0,05 % BSA and incubated subsequently for one hour at 37 °C. Following three time washing, 100l/well of TBM chromogen/substrate was pipetted into each well and incubated for 30 min at 23 °C in the dark. The color reaction was stopped by adding 100μl/well of 1M H2 SO 4 to each well and 10
Journal Pre-proof optical density was determined at 450 nm by a BMG Optima spectrophotometer. The differences between O.D. values of positive and negative sera as well as the binding ratios (O.D. values of pooled positive sera/ O.D. values of pooled negative sera) were determined. 3a. POSITIVE SERUM POOL g/ml
2
1
0,5
0,25
0,125
Blank
0,080
0,068
0,074
0,080
0,077
0,073
1:100
0,745
0,558
0,413
0,322
0,259
0,211
1:200
0,442
0,324
0,282
0,192
0,163
1:400
0,278
0,213
0,213
0,126
1:800
0,175
0,123
0,134
0,070
1:1600
0,115
0,080
0,089
0,046
1:3200
0,088
0,065
0,070
0,037
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- Coating
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0,139 0,095
0,060
0,064
0,056
0,045
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0,108
0,047
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0,033
3b. NEGATIVE SERUM POOL g/ml
2
1
Blank
0,070
0,086
1:100
0,190
0,167
1:200
0,130
0,112
1:400
0,090
1:800
0,25
0,125
0,082
0,083
0,075
0,074
0,214
0,215
0,163
0,193
0,164
0,098
0,109
0,142
0,077
0,100
0,077
0,085
0,111
0,070
0,051
0,067
0,042
0,067
0,088
1:1600
0,050
0,042
0,050
0,045
0,055
0,070
1:3200
0,050
0,039
0,057
0,039
0,039
0,070
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0,5
- Coating
3c. BINDING RATIOS g/ml
2
1
0,5
0,25
0,125
Blank
1,143
0,791
0,902
0,964
1,027
0,986
1:100
3,921
3,341
1,930
1,498
1,589
1,093
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- Coating
Journal Pre-proof 1:200
3,400
2,893
1,720
1,959
1,495
0,979
1:400
3,089
2,766
2,130
1,636
1,271
0,856
1:800
2,500
2,412
2,000
1,667
0,896
0,727
1:1600
2,300
1,905
1,780
1,022
1,018
0,643
1:3200
1,760
1,667
1,228
0,949
0,846
0,671
Table 3.: Immunoreactivity of pooled positive and negative serum samples with C. difficile
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Toxin A antigen. Table 3a: Measured O.D. values of positive serum pool on C. difficile Toxin
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A coated immunoplate. 3b: O.D. values of negative serum pool. 3c: Calculated binding ratios
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(O.D of positive serum pools/O.D of negative serum pools). The concentration of antigen
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used for titration is indicated on the top line of the tables.
4a. POSITIVE SERUM POOL g/ml
1
0,5
Blank
0,076
0,075
1:100
4,425
3,337
1:200
3,558
1:400
0,125
0,0625
0,071
0,067
0,079
0,077
2,744
2,016
1,466
0,877
2,867
2,232
1,565
1,049
0,565
2,824
2,216
1,674
1,148
0,745
0,345
1:800
2,060
1,497
1,066
0,728
0,475
0,187
1:1600
1,318
0,869
0,606
0,446
0,289
0,096
1:3200
0,760
0,501
0,351
0,252
0,159
0,047
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0,25
- Coating
4b. NEGATIVE SERUM POOL g/ml
1
0,5
0,25
0,125
0,0625
Blank
0,075
0,085
0,076
0,079
0,077
0,069
1:100
0,391
0,342
0,319
0,295
0,294
0,298
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- Coating
Journal Pre-proof 1:200
0,263
0,209
0,295
0,182
0,179
0,196
1:400
0,187
0,144
0,134
0,112
0,116
0,116
1:800
0,113
0,083
0,084
0,061
0,063
0,090
1:1600
0,092
0,056
0,060
0,048
0,051
0,066
1:3200
0,079
0,037
0,052
0,023
0,035
0,058
g/ml
1
0,5
0,25
0,125
0,0625
Blank
1,013
0,882
0,934
0,848
1,026
1,116
1:100
11,317
9,757
8,602
6,834
4,986
2,943
1:200
13,529
13,718
7,566
8,599
5,860
2,883
1:400
15,102
15,389
12,493
10,250
6,422
2,974
1:800
18,230
18,036
12,690
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4c. BINDING RATIOS
7,540
2,078
1:1600
14,326
15,518
10,100
9,292
5,667
1,455
1:3200
9,620
13,541
6,750
10,957
4,543
0,810
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11,934
- Coating
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Table 4: Immunoreactivity of pooled positive and negative sera with C. difficile Toxin B.
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Table 4a: Measured O.D. values of positive serum pool. 4b: O.D. values of negative serum pool. 4c: Calculated binding ratios (O.D of positive serum pools/O.D of negative serum pools). The concentration of antigen used for titration is indicated on the top line of the tables. In anti-Toxin-A CBT, the best binding ratio (3,921) was observed when test wells were coated with 2 g/ml of Toxin A and the pooled positive and negative sera were used at a dilution of 1:100 (Table 3). In the case of Toxin-B CBT assay, the highest binding ratio was seen when 1 g/ml (18,230) or 0,5 g/ml (18,036) of Toxin B protein was used for coating and 1:800 serum dilution was applied during the assay (Table 4). Finally, the coating concentration of 0,5 g/ml of Toxin B antigen was chosen making it possible to distinguish
13
Journal Pre-proof accurately between specific immunoreactivity of positive serum and background binding of the negative serum samples.
2. Step: Titration of secondary antibody to a single dilution of pooled positive sera on a Toxin A and B coated immunoplate The test conditions of the assays were chosen during the initial CBT and were as
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follows: coating buffer: TRIS (pH 6,5); antigen: 1 g/ml for Toxin A and 0,5 g/ml for Toxin
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B; coating: overnight at 4 °C; blocking buffer: Superblock buffer for 30 min at room
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temperature. Pooled positive serum was used at a dilution of 1:100 for Toxin-A and 1:800 for anti-Toxin B ELISA. The secondary antibody (goat anti-human Ig-HRP conjugate) was tested
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at a dilution of 1:30000,1:40000 and 1:50000. Since the 1: 30000 dilution gave the highest
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specific signal-to-noise value we chose this concentration for the final assay (Table 5).
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Toxin A 1:30000
Coated wells
2,108
1,626
Non-coated wells
1,485
0,623
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Signal to noise
1:40000 1:50000
1:30000
1:40000
1:50000
1,307
3,558
3,160
2,814
1,120
0,891
0,980
0,740
0,577
0,506
0,416
2,578
2,420
2,237
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Secondary antibodies
Toxin B
Table 5: Determination of optimal secondary antibodies dilution used for C. difficile Toxin A and B specific antibody capture immunoassay. O.D. values of pooled positive serum samples on Toxin A and B antigen coated plate and signal-to-noise values (O.D. of coated positive – O.D. of non-coated wells) are indicated.
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Journal Pre-proof Final ELISA-Protocol: Coating antigen to microplate: Therefore 2 μg/ml Toxin-A and 0,5 μg/ml Toxin-B are separately diluted in TRIS-buffer (pH 6,5). The ELISA-microplate is coated and incubated overnight at 4ºC. Washing: The coating liquid was removed and all wells were washed. Therefore 200 μl PBS supplemented with 0,05% Tween was filled in each well, then the solution was removed by
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flicking the plate over a sink. Remaining drops were removed by patting the microplate upside down on a paper towel. This whole procedure was repeated three times.
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Blocking: 200 μl/well Superblock blocking solution was added and incubated for 30 minutes
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at room temperature. Then the microplate was washed again with PBS-Tween three times.
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Incubation of primary antibody: The serum of the patients was diluted 1:100 for Toxin A and 1:800 for Toxin B in PBS-Tween (PBST). Then 100 μl of the solutions were filled in the
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adequate wells and empty wells were filled only with PBST buffer. The microplate was
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incubated for 60 minutes at 37 °C. In the meantime the PBST-BSA solution for the secondary
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antibodies was prepared by dissolving 0,2 g BSA in 40 ml PBS-Tween. The PBST-BSA solution was incubated in 37 °C until the primary antibody was ready for continuing the protocol.
Incubation of secondary antibody: The washing procedure was performed three times before continuing with preparing the 1:30000 goat anti-human Ig-HRP secondary antibody solution in PBST-BSA. 100 μl of the diluted secondary antibody solution was filled in the adequate wells, the empty wells were filled with the PBS-BSA-solution without antibody. The microplate was then incubated again for 60 minutes at 37 °C. Visualisation: The liquid was removed and the wells were filled with 200 µl PBS supplemented with 0,05% Tween for washing. This step was repeated two more times. Each 15
Journal Pre-proof well was filled with 100μl of TMB chromogen/substrate solution. Then the microplate was covered against light and incubated for 30 minutes at 23 °C. Stoping the reaction: The reaction was stopped by adding 100 μl of 1 M H2 SO 4 in each well. Measuring:
The
light-absorption
was
measured
at
450
nm
by
BMG
Optima
spectrophotometer. Statistical analysis of the data: In order to compare data of all groups, multiple analysis with
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software SPSS version 20 was performed. Multiple comparisons were made using the oneway ANOVA with Bonferroni correction. Differences were considered significant if the P-
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Results:
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value was equal to or less than 0,05.
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The development of an ELISA which can specifically test for antibodies only against
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toxigenic C. difficile strains was successful. Moreover, our test was able to determine the level of toxin-specific antibody in patients serum and could distinguish between toxin-A and
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toxin-B specific immunoreactivity. The major advantages of our method are its short
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turnaround time and its easy handling. Furthermore, since serum samples are easy to store, therefore later repeating the test or re-evaluation of the obtained result is also possible. On the other hand, the average cost of the assay /patient - is not yet calculable, since this ELISA is not an industrial testing kit. For the development of the ELISA assay we examined many different materials and reagents. We also tested various materials and concentrations for coating buffers, blocking solutions and toxin-dilution (Table 6). All of these trials were counterchecked by using positive and negative serum controls. Small adjustments to the incubation time were also made.
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Journal Pre-proof Test components Puffer
Blocking solutions
Toxin-dilutions in TRIS-buffer:
(concentration)
toxin (µg/ml) + patients serum
TRIS-buffer
Gelatine
Toxin-A
(pH 6,5)
(0,5%)
(0,125 – 0,25 – 0,5 – 1 - 2 µg/ml)
Carbonate-puffer BSA Tested
Toxin-B in TRIS-buffer
(pH 9,6)
(0,1- 1 – 3 - 5%)
PBS-puffer
Skimmed milk
(pH 7,4)
(0,1- 1 – 3 - 5%)
(0,625 – 0,125 – 0,25 – 0,5 - 1 µg/ml)
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Materials
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Superblock
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Table 6.: Tested materials during assay development
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In the next step, 62 serum samples were tested. The age of all patients was 66,4 years in average. The control group with 43,5 (22-58) years was significantly younger than the
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primary CDI and recurrent CDI group with 72,4 (34-90) and 75,7 (64-88) years, respectively.
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ELISA assay measures optical density, which in the case of antibody-capture ELISA
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correlates with the amount of antibodies in the serum. Therefore, it is possible to make a statement about the quantity of antibody present in the serum. In our first test series, the pvalue was above 0,05 and thus obtained results were not significant. Nevertheless, we can report some interesting trend which can be seen in the obtained results as follows: (1) Primary CDI patients seem to have a considerably higher level of antibodies against C. difficile toxinA and toxin-B antigens, compared to the non-infected healthy control and recurrent CDI group (Figure 1, Table 7).
(2) Interestingly, levels of toxin-B specific antibodies did not
deviate as much in the control and recurrent CDI group, but varied widely in the primary CDI group. (Table 8). While in the control and recurrent CDI groups toxin B-specific antibody
17
Journal Pre-proof levels were quite low, the primary CDI group outmatched their levels by far in average (Figure 2).
Toxin A 0,3 0,25 0,2 0,15
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0,1
0
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0,05
Recurrent CDI
Primary CDI
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Control
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Figure 1.: Graphic presentation of the amount of antibodies against Toxin-A y-axis: Optical density by 450 nm Control Group
Primary CDI
Recurrent CDI
Mean
0,07
0,19
0,09
n (persons)
15
26
20
STDEV
0,13
0,45
0,32
SEM
0,03
0,08
0,07
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Toxin-A
Table 7.: Statistical evaluation of antibody quantity against Toxin-A per group STDEV: standard deviation, SEM: standard error of the mean
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Journal Pre-proof
Toxin B 0,3 0,25 0,2
0,15 0,1
Primary CDI
Control
Recurrent CDI
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0
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0,05
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Figure 2.: Graphic presentation of amount of antibodies against toxin-A
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y-axis: Optical density by 450 nm
Control group
Primary CDI
Recurrent CDI
Mean
0,01
0,18
0,03
n (persons)
15
STDEV
0,02
SEM
0,004
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Toxin-B
19
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0,43
0,03
0,08
0,01
Table 8.: Statistical evaluation of antibody quantity against toxin-B per group STDEV: standard deviation, SEM: standard error of the mean
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Journal Pre-proof Discussion Using ELISA techniques for measuring serum antibody responses quantitatively is a widely accepted and traditional method both in diagnostic as well as in research areas. In the case of C. difficile immunity, a commercial serological test is not available up to this point. Several independent developed and standardized non-commercial ELISA tests exist for research purposes and deliver reliable data about host systemic immune response following C.difficile infection (Bauer et al. 2014; Johnson, Gerding, and Janoff 1992; Kyne et al. 2001;
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Negm et al. 2017; Sánchez-Hurtado et al. 2008). However, current knowledge on this topic is very limited and sometimes even controversial. For a better understanding and future research
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of humoral immunity against C.difficile, we aimed at developing a traditional standardized
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sandwich ELISA method for detecting human serum C.difficile toxin-A and -B specific
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antibodies.
As a result of our work, we successfully established a useful ELISA protocol to detect
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and measure C. difficile Toxin-A and Toxin-B specific antibodies in human serum. The
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estimated turnaround time is 6-7 hours, which is acceptable for clinical use. As mentioned
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earlier, it is of advantage that the test detects only toxin specific antibodies. Only a couple of studies have investigated the immune response against nontoxin antigens, e.g. surface layer proteins demonstrating comparable antibody levels in CDI patients, asymptomatic carriers and healthy controls (Bauer et al. 2014; Drudy et al. 2004; Kelly and Kyne 2011; SánchezHurtado et al. 2008; Wright et al. 2008). As a result of intestinal colonisation and/or repeated exposure to the environmental bacterium, even healthy individuals may carry C. difficile specific antibodies (Salcedo et al. 1997; Viscidi et al. 1983). However, antibody levels will further rise during and after C. difficile infection. Several clinical studies confirmed the protective role of adequate humoral immunity in the course of CDI and possible recurrence. For this reason, intravenous immunoglobulin has been used off-label for CDI treatment (Abougergi and Kwon 2011; 20
Journal Pre-proof Negm et al. 2017; O’Horo and Safdar 2009; Salcedo et al. 1997; Shah et al. 2014). It was demonstrated that serum anti-toxin A IgG response to the previous colonisation with C. difficile may reduce the risk of developing symptomatic CDI in the future (Kyne et al. 2000). Furthermore, during primary CDI, higher levels of toxin A specific IgM and IgG were found to be protective against recurrent infection and median IgG titer was associated with 30 day all-cause mortality (Kyne et al. 2001; Solomon et al. 2013). Other studies revealed the protective role of high serum toxin B antibody concentration as well (Bauer et al. 2014; Gupta
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et al. 2016; Leav et al. 2010). In cystic fibrosis patients, high anti-toxin antibody levels may explain the rare occurrence of symptomatic C.difficile infections among this vulnerable
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population (Monaghan et al. 2013, 2017).
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In our hands, both anti-toxin A and anti-toxin B antibody levels were detectable in the
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sera of healthy blood donors. Compared to these controls, patients with primary CDI showed elevated levels of toxin A and toxin B specific antibodies but the difference did not reach the
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level of significance. In patients with recurrent CDI, antibody levels decrease to the level of
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healthy controls in both cases of toxin A and toxin B. Our results are in line with previous
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findings discussed above, where similar, but significant changes of humoral immunity against C. difficile regarding primary infection and recurrence were described. Limitations of the study are the small sample size of the groups and age difference between the control group and CDI patients, since CDI patients were significantly older than healthy blood donors. However, current knowledge suggests no influence of age on serum antibody levels (Kyne et al. 2000, 2001). Considering our findings and final assumption of a correlation between decreased antibody levels and recurrence of CDI, our developed ELISA test could help to conduct further research and it might be helpful in clinical use to detect patients of high risk for CDI recurrence.
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Conflict of Interest: The authors declare that they have no conflict of interest. Ethical approval: All procedures performed were in accordance and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards and ethical approval was
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obtained from the local ethical committee of the Medical School of the University of Pécs.
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Journal Pre-proof References Abougergi MS, Kwon JH. Intravenous immunoglobulin for the treatment of Clostridium difficile infection: a review. Dig Dis Sci. 2011;56(1):19-26. doi:10.1007/s10620-0101411-2 Bauer MP, Nibbering PH, Poxton IR, Kuijper EJ, van Dissel JT. Humoral immune response as predictor of recurrence in Clostridium difficile infection. Clin Microbiol Infect. 2014;20(12):1323-1328. doi:10.1111/1469-0691.12769 Curry SR, Marsh JW, Muto CA, O’Leary MM, Pasculle AW, Harrison LH. tcdC genotypes associated with severe TcdC truncation in an epidemic clone and other strains of Clostridium difficile. J Clin Microbiol. 2007;45(1):215-221. doi:10.1128/JCM.01599-06
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Davies KA, Longshaw CM, Davis GL, et al. Underdiagnosis of Clostridium difficile across Europe: the European, multicentre, prospective, biannual, point-prevalence study of Clostridium difficile infection in hospitalised patients with diarrhoea (EUCLID). Lancet Infect Dis. 2014;14(12):1208-1219. doi:10.1016/S1473-3099(14)70991-0
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Deshpande A, Pasupuleti V, Thota P, et al. Risk factors for recurrent Clostridium difficile infection: a systematic review and meta-analysis. Infect Control Hosp Epidemiol. 2015;36(4):452-460. doi:10.1017/ice.2014.88
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Drudy D, Calabi E, Kyne L, et al. Human antibody response to surface layer proteins in Clostridium difficile infection. FEMS Immunol Med Microbiol. 2004;41(3):237-242. doi:10.1016/j.femsim.2004.03.007
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Gupta SB, Mehta V, Dubberke ER, et al. Antibodies to Toxin B Are Protective Against Clostridium difficile Infection Recurrence. Clin Infect Dis. 2016;63(6):730-734. doi:10.1093/cid/ciw364
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Johnson S, Gerding DN, Janoff EN. Systemic and mucosal antibody responses to toxin A in patients infected with Clostridium difficile. J Infect Dis. 1992;166(6):1287-1294. doi:10.1093/infdis/166.6.1287 Kelly CP, Kyne L. The host immune response to Clostridium difficile. J Med Microbiol. 2011;60(Pt 8):1070-1079. doi:10.1099/jmm.0.030015-0 Kwon JH, Olsen MA, Dubberke ER. The morbidity, mortality, and costs associated with Clostridium difficile infection. Infect Dis Clin North Am. 2015;29(1):123-134. doi:10.1016/j.idc.2014.11.003 Kyne L, Warny M, Qamar A, Kelly CP. Asymptomatic carriage of Clostridium difficile and serum levels of IgG antibody against toxin A. N Engl J Med. 2000;342(6):390-397. doi:10.1056/NEJM200002103420604 Kyne L, Warny M, Qamar A, Kelly CP. Association between antibody response to toxin A and protection against recurrent Clostridium difficile diarrhoea. Lancet. 2001;357(9251):189-193. doi:10.1016/S0140-6736(00)03592-3 Leav BA, Blair B, Leney M, et al. Serum anti-toxin B antibody correlates with protection from recurrent Clostridium difficile infection (CDI). Vaccine. 2010;28(4):965-969. 23
Journal Pre-proof doi:10.1016/j.vaccine.2009.10.144 Loo VG, Poirier L, Miller MA, et al. A predominantly clonal multi- institutional outbreak of Clostridium difficile-associated diarrhea with high morbidity and mortality. N Engl J Med. 2005;353(23):2442-2449. doi:10.1056/NEJMoa051639 Martin JSH, Monaghan TM, Wilcox MH. Clostridium difficile infection: epidemiology, diagnosis and understanding transmission. Nat Rev Gastroenterol Hepatol. 2016;13(4):206-216. doi:10.1038/nrgastro.2016.25 McEllistrem MC, Carman RJ, Gerding DN, Genheimer CW, Zheng L. A hospital outbreak of Clostridium difficile disease associated with isolates carrying binary toxin genes. Clin Infect Dis. 2005;40(2):265-272. doi:10.1086/427113
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Monaghan TM. New perspectives in Clostridium difficile disease pathogenesis. Infect Dis Clin North Am. 2015;29(1):1-11. doi:10.1016/j.idc.2014.11.007
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Monaghan TM, Negm OH, MacKenzie B, et al. High prevalence of subclass-specific binding and neutralizing antibodies against Clostridium difficile toxins in adult cystic fibrosis sera: possible mode of immunoprotection against symptomatic C. difficile infection. Clin Exp Gastroenterol. 2017;10:169-175. doi:10.2147/CEG.S133939
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Monaghan TM, Robins A, Knox A, Sewell HF, Mahida YR. Circulating antibody and memory B-Cell responses to C. difficile toxins A and B in patients with C. difficileassociated diarrhoea, inflammatory bowel disease and cystic fibrosis. PLoS One. 2013;8(9):e74452. doi:10.1371/journal.pone.0074452
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Negm OH, MacKenzie B, Hamed MR, et al. Protective antibodies against Clostridium difficile are present in intravenous immunoglobulin and are retained in humans following its administration. Clin Exp Immunol. 2017;188(3):437-443. doi:10.1111/cei.12946
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O’Horo J, Safdar N. The role of immunoglobulin for the treatment of Clostridium difficile infection: a systematic review. Int J Infect Dis. 2009;13(6):663-667. doi:10.1016/j.ijid.2008.11.012 Salcedo J, Keates S, Pothoulakis C, et al. Intravenous immunoglobulin therapy for severe Clostridium difficile colitis. Gut. 1997;41(3):366-370. doi:10.1136/gut.41.3.366 Sanchez-Hurtado K, Corretge M, Mutlu E, McIlhagger R, Starr JM, Poxton IR. Systemic antibody response to Clostridium difficile in colonized patients with and without symptoms and matched controls. J Med Microbiol. 2008;57(Pt 6):717-724. doi:10.1099/jmm.0.47713-0 Shah N, Shaaban H, Spira R, Slim J, Boghossian J. Intravenous immunoglobulin in the treatment of severe clostridium difficile colitis. J Glob Infect Dis. 2014;6(2):82-85. doi:10.4103/0974-777X.132053 Solomon K, Martin AJ, O’Donoghue C, et al. Mortality in patients with Clostridium difficile infection correlates with host pro-inflammatory and humoral immune responses. J Med Microbiol. 2013;62(Pt 9):1453-1460. doi:10.1099/jmm.0.058479-0 Viscidi R, Laughon BE, Yolken R, et al. Serum antibody response to toxins A and B of 24
Journal Pre-proof Clostridium difficile. J Infect Dis. 1983;148(1):93-100. doi:10.1093/infdis/148.1.93 Wright A, Drudy D, Kyne L, Brown K, Fairweather NF. Immunoreactive cell wall proteins of Clostridium difficile identified by human sera. J Med Microbiol. 2008;57(Pt 6):750-756. doi:10.1099/jmm.0.47532-0
*
Correspondence:
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Dr. Eva Miko M.D., Ph.D
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[email protected]
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dr. med. (Univ. Pécs) Felix Bechtolsheim M.D.
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[email protected]
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Journal Pre-proof Declaration of interests
☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
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☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests:
26
Journal Pre-proof Highlights:
f oo pr ePr al
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Recurrent Clostridium difficile infections (CDI) occurs in up to 65% in certain patient populations Quantitative testing for antibodies against toxin-A and -B in human serum can be done fast and easy The test can distinguish between toxin-A and -B immunoreactivity Patients with a single episode of CDI seem to have higher antibody levels than healthy controls and patients with recurrent CDI
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27
Felix von Bechtolsheim, Adorjan Varga, Laszlo Szereday, Beata Polgar, Timea Balassa, Bela Kocsis, Zoltan Peterfi, Eva Miko PII:
S0167-7012(19)30680-3
DOI:
https://doi.org/10.1016/j.mimet.2019.105777
Reference:
MIMET 105777
To appear in:
Journal of Microbiological Methods
Received date:
11 August 2019
Revised date:
10 November 2019
Accepted date:
12 November 2019
Please cite this article as: F. von Bechtolsheim, A. Varga, L. Szereday, et al., Development of a new serological assay for the diagnosis of Clostridium difficile infections with prognostic value, Journal of Microbiological Methods (2018), https://doi.org/10.1016/ j.mimet.2019.105777
This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
© 2018 Published by Elsevier.
Journal Pre-proof Development of a new serological assay for the diagnosis of Clostridium difficile infections with prognostic value
Felix von Bechtolsheim5 , Adorjan Varga1,3 , Laszlo Szereday1, 2 , Beata Polgar1, 2 , Timea Balassa4 , Bela Kocsis1 , Zoltan Peterfi3 , Eva Miko1, 2
Department of Medical Microbiology and Immunology, Medical School, University of Pecs,
Pecs, Hungary
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3
Janos Szentagothai Research Centre, Pecs, Hungary
1st Department of Medicine, Division of infectious diseases, Medical School, University of
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2
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Pecs, Pecs, Hungary 4
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1
Department of Medical Biology and Central Electron Microscope Laboratory, Medical
Department of Visceral-, Thoracic- and Vascular Surgery, University Hospital, Technical
*
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University Dresden
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5
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School, University of Pecs, Pecs, Hungary
Correspondence:
Dr. Eva Miko M.D., Ph.D [email protected]
1
Journal Pre-proof Abstract Purpose: The most common hospital-acquired enteral infection is caused by Clostridium difficile. Unfortunately, Clostridium difficile infections (CDI) are of high risk to recur and little is known about how to predict recurrences. Previous findings have shown that high risk for recurrence correlates with low levels of C. difficile toxin-A and -B specific antibodies suggesting the protective role of humoral immunity against bacterial virulence factors. Therefore, the aim of this study was to develop an immunoassay, which specifically measures
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C.difficile toxin-specific antibodies in the serum that might be correlated with the risk of recurrence.
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Methods: We developed a simple ELISA to measure the quantity of toxin-A and -B-specific
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antibodies in human serum. The assay was then used to test anti-toxin immune response in
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healthy controls, in patients with primary CDI and patients with CDI recurrence. Results: The developed assay is simple, reproducible and fast. When using this test in a small
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clinical trial our results showed a trend toward a higher antibody level in those patients with
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only one episode of CDI, whereas patients with recurrent CDI had less anti-toxin A or B-
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specific antibodies in their serum indicating inadequate C. difficile anti-toxin immunity may facilitate recurrent infections.
Conclusions: It has already been observed that low antibody levels are associated with recurrent CDI (Bauer et al. 2014). The findings of our clinical trial show a similar trend. Our developed ELISA test could help to conduct further research and it might be helpful in clinical use to detect patients of high risk for CDI recurrence.
Keywords: Clostridium difficile infection; ELISA assay; recurrence; antibodies; toxins
2
Journal Pre-proof Introduction Clostridium difficile is the most common cause of hospital acquired diarrhea, a major health concern and financial burden worldwide (Davies et al. 2014; Kwon, Olsen, and Dubberke 2015; Martin, Monaghan, and Wilcox 2016).
Even though it was discovered and
described already in 1935 for the first time, it took more than 40 years to link this pathogen to its various effects on human health. The hypervirulent strain B1/NAP1/027 of this Grampositive anaerobic spore-forming bacterium is primarily responsible for most of the recent
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outbreaks (Curry et al. 2007; Loo et al. 2005; McEllistrem et al. 2005). The highly transmissible and resistant spore enables the bacterial entry into the hospital environment and
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its continuous presence may lead to colonization of hospitalized patients. The clinical
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manifestation of the infection has a wide spectrum with high mortality rates. Particularly
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worrying is the fact, that in approximately 20-30% of patients with primary infection symptoms recur and recurrence rates are even higher after secondary and tertiary C. difficile
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infections (CDI) (Deshpande et al. 2015).
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Although the pathogenesis is multifactorial, the cytopathogenic effect of the two exotoxins, A
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and B is thought to be one of the major virulence factors of C.difficile along with being able to produce an endospore (Monaghan 2015). Considering that the risk of recurrence is up to 65% in certain patient populations it would be very useful to pre-estimate this risk and adapt the therapy to the given condition. Therefore, the study aimed to develop an immunoassay, which specifically measures C.difficile toxinspecific antibodies in the serum that might be correlated with the risk of recurrence. The protocol should be reliable in sensitivity and specificity, fast, uncomplicated and if possible, inexpensive. Furthermore, the developed ELISA-assay will be tested in a small clinical trial to assess the benefits and disadvantages of the test itself.
3
Journal Pre-proof Materials and Methods Donors and Patients: Serum samples were collected by clinicians at the 1st Department of Medicine, Division of infectious diseases, Medical School, University of Pécs from December 2014 to May 2016. For measuring physiological C. difficile antibody levels, 15 serum samples were collected from anonymous blood donors without any history of C. difficile infection based on a detailed questionnaire. Additionally, 47 sera of patients with the diagnosis of CDI were analysed (age
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range 48-90; 29 women and 18 males). The diagnosis of CDI was based on the symptom diarrhoea and C. difficile toxin detection in the stool with an immune chromatography test.
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Blood samples were drawn on the 8th day of antibiotic therapy. After discharge, patients were
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followed up in order to notice recurrent CDI. According to a subsequent CDI recurrence
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(more than two weeks and less than eight weeks following the onset of the primary episode), patients were grouped in “primary CDI” and “recurrent CDI” groups. Serum samples were
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stored at -80 0 C until carrying out the experiments. Informed consent was taken from each
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donor and patient. The study was approved by the Local Ethical Committee of the Medical
Materials:
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School of the University of Pecs.
For the development of a C. difficile Toxin A and B antibody capture-ELISA test, the following reagents were used: for microplate: NUNC- MaxiSorp Immunoplate F96 (Thermo Scientific); for buffers: Trizma base (TRIS, Sigma Aldrich), Dulbecco’s PBS without Ca and Mg (PAA Laboratories GmbH); for coating: C. difficile Toxin A and Toxin B (Enzo Life Sciences), for blocking: bovine serum albumin (BSA, Sigma Aldrich), Superblock (PBS) Blocking Buffer (Thermo Scientific Inf.). Antibodies used in the ELISA test: primary antibody: rabbit polyclonal antibody to C. difficile Toxin A and Toxin B (Abcam), secondary antibody: polyclonal goat anti-rabbit immunoglobulin-HRP (DAKO), polyclonal goat anti4
Journal Pre-proof human immunoglobulin-HRP (DAKO). For detection: BD OptEIA TMB Substrate Reagent Set (Beckton Dickinson). ELISA development: Testing of different coating buffers for C. difficile anti-toxin capture ELISA For initial coating concentration 1g/ml protein was chosen for both C. difficile toxins. Three coating buffers with different pH were tested: TRIS buffer (pH 6,5), carbonate buffer (pH 9,6)
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and PBS buffer (pH 7,4). Immunoplates were coated with 100 l/well of Toxin A and Toxin B diluted in the different coating buffers and incubated overnight at 4 °C. After 3 x washing
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with PBS supplemented with 0,05% Tween washing buffer, wells were blocked with 200
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l/well of PBS supplemented with 0,5% gelatine and 0,1 % BSA for 1 hour at 37°C. Then
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plates were washed with 3 x 200 l of PBS-Tween washing buffer and rabbit polyclonal antibody to C. difficile Toxin A and Toxin B (at a dilution of 1: 100) and polyclonal goat anti-
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rabbit immunoglobulin (Ig)-HRP (at a dilution of 1: 2000) were applied as primary and
again
to
remove
the
unbound
antibody-enzyme
conjugates
and
TMB
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washed
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secondary antibodies. The plates were incubated for one hour at 37 °C. Next, the wells were
chromogen/substrate was added to develop the reaction. After 30 min (Toxin A) or 10 min (Toxin B) incubation at room temperature (RT) in the dark, the colour development was stopped by adding 100 l of 1M H2 SO 4 to the wells. The optical density (O.D.) of the coated positive (toxin coated wells + 1:100 rabbit polyclonal antibody to Toxin A/B + anti-rabbit IgHRP), coated negative (toxin coated wells + anti-rabbit Ig-HRP) and non-coated control wells (non-coated wells + 1:100 rabbit polyclonal antibody to Toxin A/B + anti-rabbit Ig-HRP) were determined at 450 nm with BMG Optima spectrophotometer. As shown in Table 1., TRIS-buffer provoked the lowest nonspecific reaction in the non-coated wells and gave the highest specific signal to noise value (O.D. of coated positive – 5
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O.D. of non-coated control wells) in both Toxin A and Toxin B ELISA.
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Journal Pre-proof TRIS buffer (pH 6,5)
Carbonate-buffer (pH 9,6) PBS buffer (pH 7,4)
coated positive: 2,694
coated positive: 2,524
coated positive: 2,908
coated negative: 0,053
coated negative: 0,001
coated negative: 0,005
non-coated control: 0,604
non-coated control: 0,826
non-coated control: 0,830
signal to noise: 2,090
signal to noise: 1,698
signal to noise: 2,078
coated positive: 3,942
coated positive: 3,562
coated positive: 3,810
coated negative: 0,000
coated negative: 0,005
coated negative: 0,006
non-coated control: 0,113
non-coated control: 0,164
non-coated control: 0,161
signal to noise: 3,829
signal to noise: 3,398
Toxin-A
signal to noise: 3,649
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Toxin-B
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Table 1.: Testing of different coating buffers. OD values of coated and non-coated control wells using different coating buffers and signal-to-noise values (O.D. of coated positive –
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Choosing the blocking buffer
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O.D. of non-coated control wells) are indicated.
In order to test the accuracy of the immunoassay, a collection of blood samples of
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definitely non-infected (negative) and definitely infected (positive) patients were gathered. The collected samples were pre-tested with C. difficile anti-toxin specific ELISA, then a negative and a positive serum pool were created by mixing the three most positive and three most negative samples, respectively. The obtained serum pools were used in further setup assays. For setup of blocking conditions three different blocking solutions were tested: skimmed milk solution (3%), BSA (5%) and Superblock buffer (Thermo Scientific). ELISAplates were coated with 1g/ml Toxin A and 0,5 g/ml Toxin B in TRIS-buffer (pH 6,5) overnight at 4 ºC. The next day the immunoplates were washed three times with PBS-Tween and 200l per well of skimmed milk and BSA solution were added to the wells for 1 hour at 7
Journal Pre-proof 37 °C. According to the manufacturer’s instruction, the Superblock buffer remained for 30 minutes on the ELISA-plates to block non-specific binding sites. After washing, 1:100 diluted positive and negative serum pools were applied to the toxin-coated and non-coated wells and incubated for 1 hour at 37°C. Then the plates were washed again and goat anti-human Ig-HRP (1:30000) was added to the wells. After one hour incubation at 37°C, the reaction was developed by TMB.
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As indicated in Table 2, the choice was made in favour of Superblock solution since
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this buffer resulted in the highest signal to noise value in the case of Toxin B (O.D. of toxin
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coated No1 wells – O.D. of non-coated No1 wells). Although 5% BSA solution was also
Toxin coated wells
Non-coated wells
1
2
3
2
3
Skimmed milk (3%)
0,555
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1
0,012
0,011
0,348
0,007
0,010
0,207
BSA (5%)
0,416
0,032
0,002
0,239
0,002
0,000
0,177
Superblock
0,573
0,021
0,002
0,376
0,004
0,000
0,197
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Toxin-B
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Toxin-A
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effective, skimmed milk solution (3%) showed less satisfying results in the experiments. Signal to noise
Toxin coated wells
Non-coated wells
Signal to noise
1
2
3
1
2
3
Skimmed milk (3%)
1,464
0,007
0,005
0,361
0,000
0,001
1,103
BSA (5%)
1,331
0,012
0,002
0,258
0,042
0,005
1,077
Superblock
1,933
0,075
0,070
0,522
0,066
0,069
1,411
Table 2.: Testing of different blocking conditions. OD values of coated and non-coated wells as well as the signal-to-noise values (O.D. of coated positive – O.D. of non-coated control wells) are indicated. Control wells: 8
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3: + 1:100 positive serum pool
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Journal Pre-proof Cross-titration The concentration of each component of the immunoassay was optimized by chessboard titration (CBT). During this process the amount of coating antigen and the dilution of primary antibody were tested against each other on a microtiter plate to examine the activities inherent at all the resulting combinations. In the case of this assay, three main test components - the antigen (C. difficile Toxin A/B), the primary antibody (positive and negative serum pool) and
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anti-species conjugate (goat anti-human Ig-HRP) - needed to be optimized. 1. Step: Titration of coating antigen to positive and negative test sera, using a goat anti-
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human Ig-HRP conjugate at a dilution recommended by the manufacturer.
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First Toxin A (titration range: 2-0,125g/ml) and Toxin B (titration range: 1-0,0625g/ml)
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were diluted in TRIS buffer (pH 6,5) and test plates were coated with 100 l/well of diluted antigens from column No1 to 5 for positive sera, and column No7 to 11 for negative sera.
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Column No6 and 12 received coating buffer only. After overnight incubation at 4 °C, plates
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were washed three times with 200 l PBS-Tween washing buffer (pH 7,4) and blocked with
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200 l/well of Superblock reagent for 30 minutes at room temperature to inhibit non-specific absorption of proteins. Then ELISA plates were washed again and two-fold serial dilutions of pooled positive and negative sera (titration range: from 1:100 to 1:3200 diluted in washing buffer) were added to the plate rows from B to G. Row A and H received sample diluent only. After incubation for 1 hour at 37 °C, plates were washed three times with washing buffer. Next 100l/well of goat anti-human Ig-HRP conjugate was added to the sample wells at a single dilution of 1:30000 in PBS-Tween supplemented with 0,05 % BSA and incubated subsequently for one hour at 37 °C. Following three time washing, 100l/well of TBM chromogen/substrate was pipetted into each well and incubated for 30 min at 23 °C in the dark. The color reaction was stopped by adding 100μl/well of 1M H2 SO 4 to each well and 10
Journal Pre-proof optical density was determined at 450 nm by a BMG Optima spectrophotometer. The differences between O.D. values of positive and negative sera as well as the binding ratios (O.D. values of pooled positive sera/ O.D. values of pooled negative sera) were determined. 3a. POSITIVE SERUM POOL g/ml
2
1
0,5
0,25
0,125
Blank
0,080
0,068
0,074
0,080
0,077
0,073
1:100
0,745
0,558
0,413
0,322
0,259
0,211
1:200
0,442
0,324
0,282
0,192
0,163
1:400
0,278
0,213
0,213
0,126
1:800
0,175
0,123
0,134
0,070
1:1600
0,115
0,080
0,089
0,046
1:3200
0,088
0,065
0,070
0,037
f
- Coating
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0,139 0,095
0,060
0,064
0,056
0,045
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pr
0,108
0,047
Pr
0,033
3b. NEGATIVE SERUM POOL g/ml
2
1
Blank
0,070
0,086
1:100
0,190
0,167
1:200
0,130
0,112
1:400
0,090
1:800
0,25
0,125
0,082
0,083
0,075
0,074
0,214
0,215
0,163
0,193
0,164
0,098
0,109
0,142
0,077
0,100
0,077
0,085
0,111
0,070
0,051
0,067
0,042
0,067
0,088
1:1600
0,050
0,042
0,050
0,045
0,055
0,070
1:3200
0,050
0,039
0,057
0,039
0,039
0,070
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0,5
- Coating
3c. BINDING RATIOS g/ml
2
1
0,5
0,25
0,125
Blank
1,143
0,791
0,902
0,964
1,027
0,986
1:100
3,921
3,341
1,930
1,498
1,589
1,093
11
- Coating
Journal Pre-proof 1:200
3,400
2,893
1,720
1,959
1,495
0,979
1:400
3,089
2,766
2,130
1,636
1,271
0,856
1:800
2,500
2,412
2,000
1,667
0,896
0,727
1:1600
2,300
1,905
1,780
1,022
1,018
0,643
1:3200
1,760
1,667
1,228
0,949
0,846
0,671
Table 3.: Immunoreactivity of pooled positive and negative serum samples with C. difficile
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Toxin A antigen. Table 3a: Measured O.D. values of positive serum pool on C. difficile Toxin
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A coated immunoplate. 3b: O.D. values of negative serum pool. 3c: Calculated binding ratios
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(O.D of positive serum pools/O.D of negative serum pools). The concentration of antigen
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used for titration is indicated on the top line of the tables.
4a. POSITIVE SERUM POOL g/ml
1
0,5
Blank
0,076
0,075
1:100
4,425
3,337
1:200
3,558
1:400
0,125
0,0625
0,071
0,067
0,079
0,077
2,744
2,016
1,466
0,877
2,867
2,232
1,565
1,049
0,565
2,824
2,216
1,674
1,148
0,745
0,345
1:800
2,060
1,497
1,066
0,728
0,475
0,187
1:1600
1,318
0,869
0,606
0,446
0,289
0,096
1:3200
0,760
0,501
0,351
0,252
0,159
0,047
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0,25
- Coating
4b. NEGATIVE SERUM POOL g/ml
1
0,5
0,25
0,125
0,0625
Blank
0,075
0,085
0,076
0,079
0,077
0,069
1:100
0,391
0,342
0,319
0,295
0,294
0,298
12
- Coating
Journal Pre-proof 1:200
0,263
0,209
0,295
0,182
0,179
0,196
1:400
0,187
0,144
0,134
0,112
0,116
0,116
1:800
0,113
0,083
0,084
0,061
0,063
0,090
1:1600
0,092
0,056
0,060
0,048
0,051
0,066
1:3200
0,079
0,037
0,052
0,023
0,035
0,058
g/ml
1
0,5
0,25
0,125
0,0625
Blank
1,013
0,882
0,934
0,848
1,026
1,116
1:100
11,317
9,757
8,602
6,834
4,986
2,943
1:200
13,529
13,718
7,566
8,599
5,860
2,883
1:400
15,102
15,389
12,493
10,250
6,422
2,974
1:800
18,230
18,036
12,690
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4c. BINDING RATIOS
7,540
2,078
1:1600
14,326
15,518
10,100
9,292
5,667
1,455
1:3200
9,620
13,541
6,750
10,957
4,543
0,810
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pr
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11,934
- Coating
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Table 4: Immunoreactivity of pooled positive and negative sera with C. difficile Toxin B.
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Table 4a: Measured O.D. values of positive serum pool. 4b: O.D. values of negative serum pool. 4c: Calculated binding ratios (O.D of positive serum pools/O.D of negative serum pools). The concentration of antigen used for titration is indicated on the top line of the tables. In anti-Toxin-A CBT, the best binding ratio (3,921) was observed when test wells were coated with 2 g/ml of Toxin A and the pooled positive and negative sera were used at a dilution of 1:100 (Table 3). In the case of Toxin-B CBT assay, the highest binding ratio was seen when 1 g/ml (18,230) or 0,5 g/ml (18,036) of Toxin B protein was used for coating and 1:800 serum dilution was applied during the assay (Table 4). Finally, the coating concentration of 0,5 g/ml of Toxin B antigen was chosen making it possible to distinguish
13
Journal Pre-proof accurately between specific immunoreactivity of positive serum and background binding of the negative serum samples.
2. Step: Titration of secondary antibody to a single dilution of pooled positive sera on a Toxin A and B coated immunoplate The test conditions of the assays were chosen during the initial CBT and were as
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follows: coating buffer: TRIS (pH 6,5); antigen: 1 g/ml for Toxin A and 0,5 g/ml for Toxin
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B; coating: overnight at 4 °C; blocking buffer: Superblock buffer for 30 min at room
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temperature. Pooled positive serum was used at a dilution of 1:100 for Toxin-A and 1:800 for anti-Toxin B ELISA. The secondary antibody (goat anti-human Ig-HRP conjugate) was tested
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at a dilution of 1:30000,1:40000 and 1:50000. Since the 1: 30000 dilution gave the highest
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specific signal-to-noise value we chose this concentration for the final assay (Table 5).
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Toxin A 1:30000
Coated wells
2,108
1,626
Non-coated wells
1,485
0,623
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Signal to noise
1:40000 1:50000
1:30000
1:40000
1:50000
1,307
3,558
3,160
2,814
1,120
0,891
0,980
0,740
0,577
0,506
0,416
2,578
2,420
2,237
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Secondary antibodies
Toxin B
Table 5: Determination of optimal secondary antibodies dilution used for C. difficile Toxin A and B specific antibody capture immunoassay. O.D. values of pooled positive serum samples on Toxin A and B antigen coated plate and signal-to-noise values (O.D. of coated positive – O.D. of non-coated wells) are indicated.
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Journal Pre-proof Final ELISA-Protocol: Coating antigen to microplate: Therefore 2 μg/ml Toxin-A and 0,5 μg/ml Toxin-B are separately diluted in TRIS-buffer (pH 6,5). The ELISA-microplate is coated and incubated overnight at 4ºC. Washing: The coating liquid was removed and all wells were washed. Therefore 200 μl PBS supplemented with 0,05% Tween was filled in each well, then the solution was removed by
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flicking the plate over a sink. Remaining drops were removed by patting the microplate upside down on a paper towel. This whole procedure was repeated three times.
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Blocking: 200 μl/well Superblock blocking solution was added and incubated for 30 minutes
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at room temperature. Then the microplate was washed again with PBS-Tween three times.
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Incubation of primary antibody: The serum of the patients was diluted 1:100 for Toxin A and 1:800 for Toxin B in PBS-Tween (PBST). Then 100 μl of the solutions were filled in the
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adequate wells and empty wells were filled only with PBST buffer. The microplate was
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incubated for 60 minutes at 37 °C. In the meantime the PBST-BSA solution for the secondary
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antibodies was prepared by dissolving 0,2 g BSA in 40 ml PBS-Tween. The PBST-BSA solution was incubated in 37 °C until the primary antibody was ready for continuing the protocol.
Incubation of secondary antibody: The washing procedure was performed three times before continuing with preparing the 1:30000 goat anti-human Ig-HRP secondary antibody solution in PBST-BSA. 100 μl of the diluted secondary antibody solution was filled in the adequate wells, the empty wells were filled with the PBS-BSA-solution without antibody. The microplate was then incubated again for 60 minutes at 37 °C. Visualisation: The liquid was removed and the wells were filled with 200 µl PBS supplemented with 0,05% Tween for washing. This step was repeated two more times. Each 15
Journal Pre-proof well was filled with 100μl of TMB chromogen/substrate solution. Then the microplate was covered against light and incubated for 30 minutes at 23 °C. Stoping the reaction: The reaction was stopped by adding 100 μl of 1 M H2 SO 4 in each well. Measuring:
The
light-absorption
was
measured
at
450
nm
by
BMG
Optima
spectrophotometer. Statistical analysis of the data: In order to compare data of all groups, multiple analysis with
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software SPSS version 20 was performed. Multiple comparisons were made using the oneway ANOVA with Bonferroni correction. Differences were considered significant if the P-
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Results:
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value was equal to or less than 0,05.
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The development of an ELISA which can specifically test for antibodies only against
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toxigenic C. difficile strains was successful. Moreover, our test was able to determine the level of toxin-specific antibody in patients serum and could distinguish between toxin-A and
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toxin-B specific immunoreactivity. The major advantages of our method are its short
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turnaround time and its easy handling. Furthermore, since serum samples are easy to store, therefore later repeating the test or re-evaluation of the obtained result is also possible. On the other hand, the average cost of the assay /patient - is not yet calculable, since this ELISA is not an industrial testing kit. For the development of the ELISA assay we examined many different materials and reagents. We also tested various materials and concentrations for coating buffers, blocking solutions and toxin-dilution (Table 6). All of these trials were counterchecked by using positive and negative serum controls. Small adjustments to the incubation time were also made.
16
Journal Pre-proof Test components Puffer
Blocking solutions
Toxin-dilutions in TRIS-buffer:
(concentration)
toxin (µg/ml) + patients serum
TRIS-buffer
Gelatine
Toxin-A
(pH 6,5)
(0,5%)
(0,125 – 0,25 – 0,5 – 1 - 2 µg/ml)
Carbonate-puffer BSA Tested
Toxin-B in TRIS-buffer
(pH 9,6)
(0,1- 1 – 3 - 5%)
PBS-puffer
Skimmed milk
(pH 7,4)
(0,1- 1 – 3 - 5%)
(0,625 – 0,125 – 0,25 – 0,5 - 1 µg/ml)
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Materials
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Superblock
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Table 6.: Tested materials during assay development
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In the next step, 62 serum samples were tested. The age of all patients was 66,4 years in average. The control group with 43,5 (22-58) years was significantly younger than the
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primary CDI and recurrent CDI group with 72,4 (34-90) and 75,7 (64-88) years, respectively.
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ELISA assay measures optical density, which in the case of antibody-capture ELISA
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correlates with the amount of antibodies in the serum. Therefore, it is possible to make a statement about the quantity of antibody present in the serum. In our first test series, the pvalue was above 0,05 and thus obtained results were not significant. Nevertheless, we can report some interesting trend which can be seen in the obtained results as follows: (1) Primary CDI patients seem to have a considerably higher level of antibodies against C. difficile toxinA and toxin-B antigens, compared to the non-infected healthy control and recurrent CDI group (Figure 1, Table 7).
(2) Interestingly, levels of toxin-B specific antibodies did not
deviate as much in the control and recurrent CDI group, but varied widely in the primary CDI group. (Table 8). While in the control and recurrent CDI groups toxin B-specific antibody
17
Journal Pre-proof levels were quite low, the primary CDI group outmatched their levels by far in average (Figure 2).
Toxin A 0,3 0,25 0,2 0,15
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0,1
0
pr
0,05
Recurrent CDI
Primary CDI
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Control
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Figure 1.: Graphic presentation of the amount of antibodies against Toxin-A y-axis: Optical density by 450 nm Control Group
Primary CDI
Recurrent CDI
Mean
0,07
0,19
0,09
n (persons)
15
26
20
STDEV
0,13
0,45
0,32
SEM
0,03
0,08
0,07
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Toxin-A
Table 7.: Statistical evaluation of antibody quantity against Toxin-A per group STDEV: standard deviation, SEM: standard error of the mean
18
Journal Pre-proof
Toxin B 0,3 0,25 0,2
0,15 0,1
Primary CDI
Control
Recurrent CDI
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0
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0,05
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Figure 2.: Graphic presentation of amount of antibodies against toxin-A
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y-axis: Optical density by 450 nm
Control group
Primary CDI
Recurrent CDI
Mean
0,01
0,18
0,03
n (persons)
15
STDEV
0,02
SEM
0,004
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Toxin-B
19
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27
0,43
0,03
0,08
0,01
Table 8.: Statistical evaluation of antibody quantity against toxin-B per group STDEV: standard deviation, SEM: standard error of the mean
19
Journal Pre-proof Discussion Using ELISA techniques for measuring serum antibody responses quantitatively is a widely accepted and traditional method both in diagnostic as well as in research areas. In the case of C. difficile immunity, a commercial serological test is not available up to this point. Several independent developed and standardized non-commercial ELISA tests exist for research purposes and deliver reliable data about host systemic immune response following C.difficile infection (Bauer et al. 2014; Johnson, Gerding, and Janoff 1992; Kyne et al. 2001;
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Negm et al. 2017; Sánchez-Hurtado et al. 2008). However, current knowledge on this topic is very limited and sometimes even controversial. For a better understanding and future research
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of humoral immunity against C.difficile, we aimed at developing a traditional standardized
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sandwich ELISA method for detecting human serum C.difficile toxin-A and -B specific
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antibodies.
As a result of our work, we successfully established a useful ELISA protocol to detect
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and measure C. difficile Toxin-A and Toxin-B specific antibodies in human serum. The
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estimated turnaround time is 6-7 hours, which is acceptable for clinical use. As mentioned
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earlier, it is of advantage that the test detects only toxin specific antibodies. Only a couple of studies have investigated the immune response against nontoxin antigens, e.g. surface layer proteins demonstrating comparable antibody levels in CDI patients, asymptomatic carriers and healthy controls (Bauer et al. 2014; Drudy et al. 2004; Kelly and Kyne 2011; SánchezHurtado et al. 2008; Wright et al. 2008). As a result of intestinal colonisation and/or repeated exposure to the environmental bacterium, even healthy individuals may carry C. difficile specific antibodies (Salcedo et al. 1997; Viscidi et al. 1983). However, antibody levels will further rise during and after C. difficile infection. Several clinical studies confirmed the protective role of adequate humoral immunity in the course of CDI and possible recurrence. For this reason, intravenous immunoglobulin has been used off-label for CDI treatment (Abougergi and Kwon 2011; 20
Journal Pre-proof Negm et al. 2017; O’Horo and Safdar 2009; Salcedo et al. 1997; Shah et al. 2014). It was demonstrated that serum anti-toxin A IgG response to the previous colonisation with C. difficile may reduce the risk of developing symptomatic CDI in the future (Kyne et al. 2000). Furthermore, during primary CDI, higher levels of toxin A specific IgM and IgG were found to be protective against recurrent infection and median IgG titer was associated with 30 day all-cause mortality (Kyne et al. 2001; Solomon et al. 2013). Other studies revealed the protective role of high serum toxin B antibody concentration as well (Bauer et al. 2014; Gupta
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et al. 2016; Leav et al. 2010). In cystic fibrosis patients, high anti-toxin antibody levels may explain the rare occurrence of symptomatic C.difficile infections among this vulnerable
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population (Monaghan et al. 2013, 2017).
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In our hands, both anti-toxin A and anti-toxin B antibody levels were detectable in the
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sera of healthy blood donors. Compared to these controls, patients with primary CDI showed elevated levels of toxin A and toxin B specific antibodies but the difference did not reach the
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level of significance. In patients with recurrent CDI, antibody levels decrease to the level of
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healthy controls in both cases of toxin A and toxin B. Our results are in line with previous
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findings discussed above, where similar, but significant changes of humoral immunity against C. difficile regarding primary infection and recurrence were described. Limitations of the study are the small sample size of the groups and age difference between the control group and CDI patients, since CDI patients were significantly older than healthy blood donors. However, current knowledge suggests no influence of age on serum antibody levels (Kyne et al. 2000, 2001). Considering our findings and final assumption of a correlation between decreased antibody levels and recurrence of CDI, our developed ELISA test could help to conduct further research and it might be helpful in clinical use to detect patients of high risk for CDI recurrence.
21
Journal Pre-proof
Conflict of Interest: The authors declare that they have no conflict of interest. Ethical approval: All procedures performed were in accordance and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards and ethical approval was
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obtained from the local ethical committee of the Medical School of the University of Pécs.
22
Journal Pre-proof References Abougergi MS, Kwon JH. Intravenous immunoglobulin for the treatment of Clostridium difficile infection: a review. Dig Dis Sci. 2011;56(1):19-26. doi:10.1007/s10620-0101411-2 Bauer MP, Nibbering PH, Poxton IR, Kuijper EJ, van Dissel JT. Humoral immune response as predictor of recurrence in Clostridium difficile infection. Clin Microbiol Infect. 2014;20(12):1323-1328. doi:10.1111/1469-0691.12769 Curry SR, Marsh JW, Muto CA, O’Leary MM, Pasculle AW, Harrison LH. tcdC genotypes associated with severe TcdC truncation in an epidemic clone and other strains of Clostridium difficile. J Clin Microbiol. 2007;45(1):215-221. doi:10.1128/JCM.01599-06
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Davies KA, Longshaw CM, Davis GL, et al. Underdiagnosis of Clostridium difficile across Europe: the European, multicentre, prospective, biannual, point-prevalence study of Clostridium difficile infection in hospitalised patients with diarrhoea (EUCLID). Lancet Infect Dis. 2014;14(12):1208-1219. doi:10.1016/S1473-3099(14)70991-0
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Deshpande A, Pasupuleti V, Thota P, et al. Risk factors for recurrent Clostridium difficile infection: a systematic review and meta-analysis. Infect Control Hosp Epidemiol. 2015;36(4):452-460. doi:10.1017/ice.2014.88
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Drudy D, Calabi E, Kyne L, et al. Human antibody response to surface layer proteins in Clostridium difficile infection. FEMS Immunol Med Microbiol. 2004;41(3):237-242. doi:10.1016/j.femsim.2004.03.007
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Gupta SB, Mehta V, Dubberke ER, et al. Antibodies to Toxin B Are Protective Against Clostridium difficile Infection Recurrence. Clin Infect Dis. 2016;63(6):730-734. doi:10.1093/cid/ciw364
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Johnson S, Gerding DN, Janoff EN. Systemic and mucosal antibody responses to toxin A in patients infected with Clostridium difficile. J Infect Dis. 1992;166(6):1287-1294. doi:10.1093/infdis/166.6.1287 Kelly CP, Kyne L. The host immune response to Clostridium difficile. J Med Microbiol. 2011;60(Pt 8):1070-1079. doi:10.1099/jmm.0.030015-0 Kwon JH, Olsen MA, Dubberke ER. The morbidity, mortality, and costs associated with Clostridium difficile infection. Infect Dis Clin North Am. 2015;29(1):123-134. doi:10.1016/j.idc.2014.11.003 Kyne L, Warny M, Qamar A, Kelly CP. Asymptomatic carriage of Clostridium difficile and serum levels of IgG antibody against toxin A. N Engl J Med. 2000;342(6):390-397. doi:10.1056/NEJM200002103420604 Kyne L, Warny M, Qamar A, Kelly CP. Association between antibody response to toxin A and protection against recurrent Clostridium difficile diarrhoea. Lancet. 2001;357(9251):189-193. doi:10.1016/S0140-6736(00)03592-3 Leav BA, Blair B, Leney M, et al. Serum anti-toxin B antibody correlates with protection from recurrent Clostridium difficile infection (CDI). Vaccine. 2010;28(4):965-969. 23
Journal Pre-proof doi:10.1016/j.vaccine.2009.10.144 Loo VG, Poirier L, Miller MA, et al. A predominantly clonal multi- institutional outbreak of Clostridium difficile-associated diarrhea with high morbidity and mortality. N Engl J Med. 2005;353(23):2442-2449. doi:10.1056/NEJMoa051639 Martin JSH, Monaghan TM, Wilcox MH. Clostridium difficile infection: epidemiology, diagnosis and understanding transmission. Nat Rev Gastroenterol Hepatol. 2016;13(4):206-216. doi:10.1038/nrgastro.2016.25 McEllistrem MC, Carman RJ, Gerding DN, Genheimer CW, Zheng L. A hospital outbreak of Clostridium difficile disease associated with isolates carrying binary toxin genes. Clin Infect Dis. 2005;40(2):265-272. doi:10.1086/427113
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Monaghan TM. New perspectives in Clostridium difficile disease pathogenesis. Infect Dis Clin North Am. 2015;29(1):1-11. doi:10.1016/j.idc.2014.11.007
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Monaghan TM, Negm OH, MacKenzie B, et al. High prevalence of subclass-specific binding and neutralizing antibodies against Clostridium difficile toxins in adult cystic fibrosis sera: possible mode of immunoprotection against symptomatic C. difficile infection. Clin Exp Gastroenterol. 2017;10:169-175. doi:10.2147/CEG.S133939
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Monaghan TM, Robins A, Knox A, Sewell HF, Mahida YR. Circulating antibody and memory B-Cell responses to C. difficile toxins A and B in patients with C. difficileassociated diarrhoea, inflammatory bowel disease and cystic fibrosis. PLoS One. 2013;8(9):e74452. doi:10.1371/journal.pone.0074452
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Negm OH, MacKenzie B, Hamed MR, et al. Protective antibodies against Clostridium difficile are present in intravenous immunoglobulin and are retained in humans following its administration. Clin Exp Immunol. 2017;188(3):437-443. doi:10.1111/cei.12946
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O’Horo J, Safdar N. The role of immunoglobulin for the treatment of Clostridium difficile infection: a systematic review. Int J Infect Dis. 2009;13(6):663-667. doi:10.1016/j.ijid.2008.11.012 Salcedo J, Keates S, Pothoulakis C, et al. Intravenous immunoglobulin therapy for severe Clostridium difficile colitis. Gut. 1997;41(3):366-370. doi:10.1136/gut.41.3.366 Sanchez-Hurtado K, Corretge M, Mutlu E, McIlhagger R, Starr JM, Poxton IR. Systemic antibody response to Clostridium difficile in colonized patients with and without symptoms and matched controls. J Med Microbiol. 2008;57(Pt 6):717-724. doi:10.1099/jmm.0.47713-0 Shah N, Shaaban H, Spira R, Slim J, Boghossian J. Intravenous immunoglobulin in the treatment of severe clostridium difficile colitis. J Glob Infect Dis. 2014;6(2):82-85. doi:10.4103/0974-777X.132053 Solomon K, Martin AJ, O’Donoghue C, et al. Mortality in patients with Clostridium difficile infection correlates with host pro-inflammatory and humoral immune responses. J Med Microbiol. 2013;62(Pt 9):1453-1460. doi:10.1099/jmm.0.058479-0 Viscidi R, Laughon BE, Yolken R, et al. Serum antibody response to toxins A and B of 24
Journal Pre-proof Clostridium difficile. J Infect Dis. 1983;148(1):93-100. doi:10.1093/infdis/148.1.93 Wright A, Drudy D, Kyne L, Brown K, Fairweather NF. Immunoreactive cell wall proteins of Clostridium difficile identified by human sera. J Med Microbiol. 2008;57(Pt 6):750-756. doi:10.1099/jmm.0.47532-0
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Correspondence:
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Dr. Eva Miko M.D., Ph.D
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[email protected]
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dr. med. (Univ. Pécs) Felix Bechtolsheim M.D.
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[email protected]
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Journal Pre-proof Declaration of interests
☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
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☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests:
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Journal Pre-proof Highlights:
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Recurrent Clostridium difficile infections (CDI) occurs in up to 65% in certain patient populations Quantitative testing for antibodies against toxin-A and -B in human serum can be done fast and easy The test can distinguish between toxin-A and -B immunoreactivity Patients with a single episode of CDI seem to have higher antibody levels than healthy controls and patients with recurrent CDI
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